CN114566334B - Insulating layer cladding equipment for cable production and application method thereof - Google Patents

Abstract

The invention discloses insulating layer coating equipment for cable production and a using method thereof, and relates to the technical field of cable coating equipment.

Description

Insulating layer cladding equipment for cable production and application method thereof

Technical Field

The invention relates to the technical field of cable cladding equipment, in particular to insulating layer cladding equipment for cable production and a using method thereof.

Background

The wire and cable are products which are increasingly relied on by people in the current generation, and are mainly used for transmitting power, and the use of mobile phones and computers generally requires the support of the power, so that people pay attention to the quality of the products when selecting the products, and the quality of the wire can be directly influenced by the quality of the wire by virtue of the wire insulating layer.

The invention with publication number CN111681840B discloses a wire and cable insulation layer coating production line. Comprises an unreeling mechanism, a coating mechanism and a reeling mechanism which are sequentially arranged. According to the invention, the unreeling mechanism and the reeling mechanism rotate, so that the wire and the cable are driven to rotate, and the problem that the coating material gathers at the bottom of the wire and the cable due to the gravity and the flowability of the coating material after the coating material coats the surface of the wire and the cable is avoided, so that the wire and the cable are uniformly coated by the coating material.

However, although the insulating layer coating can be more uniform by the method of rotating the wire core, the wire core can be damaged by rotating the wire core, only the wire core in the middle of the device is rotated, the wire cores at the two sides of the device are not rotated, the wire core is damaged by torsional force, no treatment is performed before the wire core is coated with the insulating layer, the metal wire core is stretched and preheated before entering the composite forming die, so that the metal wire core has better adhesion and small deformation with the molten material, and the wire core is fully coated by the insulating layer by rotating the coating device, so that the damage to the wire core in the prior art when the cable is coated is avoided, and therefore, the insulating layer coating equipment for cable production is needed to realize the purpose.

Disclosure of Invention

In view of the problems in the above-mentioned technologies, the present invention proposes an insulating layer coating apparatus for cable production.

The invention relates to insulating layer cladding equipment for cable production, which comprises a winding assembly, wherein the winding assembly comprises a base, two groups of winding wheels are rotatably arranged at two ends inside the base, one group of winding wheels is a winding wheel, the other group of winding wheels is a releasing wheel, one end of the base, which is close to the releasing wheel, is provided with a mounting plate, four wire pulling wheels I are rotatably arranged on the mounting plate, each two wire pulling wheels I are respectively arranged at two sides of the mounting plate, grooves are formed in the wire pulling wheels I, a bevel gear I is arranged on the wire pulling wheels I, the bevel gear I is connected with the other group of wire pulling wheels I through a belt, the diameter of the shaft of the bevel gear I is smaller than that of the wire pulling wheel I connected with the other group of wire pulling wheels I through the belt I, a rotating disc is coaxially arranged on the bevel gear I, the mounting plate is also provided with a heating wire I, the base is provided with a time delay driving component, the time delay driving component comprises a driving motor, the driving motor drives a gear III and a bevel gear II to rotate, the gear III is rotatably arranged on the base, the bevel gear II is intermittently meshed with the bevel gear I, the base is also provided with a feeding component, the feeding component comprises a supporting plate arranged on the base, the supporting plate is provided with a coating barrel, one end of the coating barrel is provided with a gear IV, the other end of the coating barrel is provided with a wire outlet, the gear IV is meshed with the gear III, the gear IV is coaxially provided with a stirring fan blade and a spiral cone, the base is also provided with a cooling component, the cooling component comprises a wire inlet connected with the wire outlet, the wire inlet is rotatably provided with a cooling barrel, the cooling barrel is provided with a plurality of groups of water collecting barrels, the whole device is driven to operate through the delay driving assembly, and the delay driving assembly can ensure that enough cables are coated in the cooling barrel.

Furthermore, the first wire pulling wheel is provided with teeth, and the two first wire pulling wheels on the same side are meshed through the teeth to drive the cable to move.

Further, the winding assembly also comprises a plurality of groups of rotating rollers which are rotatably arranged at the bottom of the base, the rotating rollers are attached to the winding wheels, the two groups of winding wheels are connected through a connecting rod, the winding wheels arranged in the winding assembly are simultaneously rotated, the regularity of cables is guaranteed, and the cables are prevented from being wound.

Further, delay drive assembly still including installing the epaxial drive gear of driving motor output, driving motor upper end be provided with gear one, gear one with drive gear meshing, gear one on be provided with protruding line pole, gear one end and drive gear meshing, gear one other end be connected with gear three through belt two, gear three coaxial be provided with gear two, gear two with gear one intermittent type meshing, gear two on be provided with concave line pole, concave line pole one end be connected with gear two, concave line pole other end be connected with bevel gear two, concave line pole and convex line pole intermittent type meshing, concave line pole slide and gear three sliding connection.

Further, the feeding assembly also comprises a feeding box arranged at the upper end of the coating barrel, the feeding box is communicated with the stirring fan blade, and a heating wire II is arranged in the gear II to heat the coating material so as to prevent the coating material from solidifying when the coating is not completed.

Further, the cooling module still be provided with the basin on the base, the entrance is rotated and is installed on the basin, the basin side rotate and be provided with the driving disk, the driving disk on be provided with the actuating post, the cooling barrel on be provided with multiunit driven piece, actuating post and driven piece meshing, the base on rotate and be provided with two and act as go-between two, two act as go-between two on be provided with the rotation tooth, two act as go-between two intermeshing, a two on acting as go-between coaxial driven disks that are provided with of acting as go-between, the driven disk on be provided with the connecting rod two, connecting rod two one end be connected with the driven disk, connecting rod two other end be connected with the rotating disk, connecting rod two middle section be connected with the driving disk, incessantly cool off the cable through a plurality of water collection buckets.

Further, the one end that the inlet wire be close to the base be provided with the water leakage mouth, the one end that the inlet wire kept away from the base be provided with the water inlet, the cooling water carries out reuse.

Further, the application method of the insulating layer coating equipment for cable production comprises the following steps:

s1, a cable passes through a groove at the rear end of a first wire pulling wheel, and is heated and stretched by a first heating wire;

s2, placing the cable stretched in the first wire pulling wheel into a feeding assembly;

s3, placing the coating raw materials into a feeding box;

s4, coating the cable through the stirring fan blade and the spiral cone blade;

s5, after the cable coating is finished, the cable enters a wire inlet through a wire outlet;

s6, continuously pouring water in the water tank into the wire inlet by the water collecting barrel, and cooling the cable coated in the wire inlet;

s7, winding the coated cable on the winding wheel again.

Compared with the prior art, the invention has the beneficial effects that: (1) According to the invention, the winding and unwinding of the cable can be realized simultaneously through the winding component, so that the cable is prevented from winding in the coating process; (2) According to the invention, the cable can be heated and stretched in real time through the stretching assembly, so that the coating integrity of the cable is ensured; (3) According to the invention, the delay driving assembly is arranged to ensure that the cable is only coated when enough cables exist in the cable; (4) The feeding component can uniformly and completely coat the cable through the spiral conical sheet, and the cable cannot be damaged; (5) According to the invention, the cooling assembly is arranged to cool the coated cable uninterruptedly, so that the cooling efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention.

FIG. 2 is a partial cross-sectional view of the winding assembly of the present invention.

FIG. 3 is a schematic view of the stretching assembly of the present invention.

Fig. 4 is a schematic structural diagram of the delay driving component of the present invention.

FIG. 5 is a schematic view of the feed assembly of the present invention.

Fig. 6 is a cross-sectional view of the feed assembly of the present invention.

FIG. 7 is a schematic view of a cooling module according to the present invention.

FIG. 8 is a schematic view of a partial structure of a cooling module according to the present invention.

Reference numerals: 1-a winding assembly; 2-stretching assembly; 3-a delay driving component; 4-a feed assembly; 5-cooling the assembly; 101-a base; 102-rotating a roller; 103-a reel; 104-a first connecting rod; 201-mounting plates; 202-a first wire pulling wheel; 203-a first bevel gear; 204-rotating a disc; 205-belt one; 206, heating wire I; 301-driving a motor; 302-a drive gear; 303-gear one; 304-gear two; 305-a dimpled bar; 306-a bump bar; 307-belt two; 308-gear three; 309-bevel gear two; 401-supporting plates; 402-coating a barrel; 403-feeding box; 404-gear four; 405-stirring fan blades; 406-heating wire II; 407-spiral cone sheet; 408-outlet; 501-cooling barrels; 502-a driven block; 503-drive the disk; 504-a sink; 505-water collecting barrel; 506-a wire inlet; 507-second connecting rod; 508-driven plate; 509-wire pulling wheel two.

Detailed Description

Specific embodiments of the device according to the invention are further described below with reference to the drawings and exemplary embodiments.

Examples: referring to fig. 1, the insulating layer coating equipment for cable production comprises a winding assembly 1 provided with two winding wheels 103, wherein the winding assembly 1 is used for placing an uncoated cable and a coated cable, a stretching assembly 2 used for heating and stretching the cable is arranged at the upper end of the winding assembly 1, a delay driving assembly 3 used for controlling the cable to enter the insulating layer coating equipment and then coating the cable is arranged on the stretching assembly 2, a feeding assembly 4 used for heating a coating raw material and coating the cable through a spiral cone is arranged on the delay driving assembly 3, and a cooling assembly 5 used for continuously spraying water to the coated cable is arranged at the rear end of the feeding assembly 4.

Referring to fig. 1 and 2, the winding assembly 1 includes a base 101, two sets of winding wheels 103 are rotatably disposed in the base 101, eight rotating rollers 102 are disposed at the lower end of each set of winding wheels 103, the rotating rollers 102 are rotatably mounted at the lower end of the base 101, one set of winding wheels 103 is a winding wheel, the other set of winding wheels 103 is a unwinding wheel, the two sets of winding wheels 103 are synchronously rotated through a connection rod 104, a cable wrapped with an insulating layer is wound on the winding wheel, and a cable not wrapped with the insulating layer is wound on the unwinding wheel.

Referring to fig. 1 and 3, the stretching assembly 2 includes a mounting plate 201 mounted on a base 101, four wire pulling wheels 202 are rotatably mounted on the mounting plate 201, each two wire pulling wheels 202 are respectively mounted on two sides of the mounting plate 201, grooves and teeth are formed in the wire pulling wheels 202, two wire pulling wheels 202 on the same side are meshed through the teeth, a bevel gear 203 is coaxially arranged in one wire pulling wheel 202, the bevel gear 203 is connected with the other wire pulling wheel 202 through a belt 205, the shaft diameter of the bevel gear 203 is smaller than that of the wire pulling wheel 202 connected with the other wire pulling wheel 205, a rotating disc 204 is coaxially arranged on the bevel gear 203, a heating wire 206 is arranged on the mounting plate 201, when the bevel gear 203 is driven, the two wire pulling wheels 202 rotate simultaneously, a driving cable moves in the grooves, and meanwhile the heating wire 206 heats the cable, and the rotating speed of the bevel gear is deviated due to the fact that the sizes of the bevel gear 203 and the rotating shafts of the wire pulling wheels 202 are different.

Referring to fig. 1 and 4, the delay driving component 3 includes a driving motor 301 installed on the base 101, a driving gear 302 is disposed on an output shaft of the driving motor 301, a first gear 303 is rotatably disposed at an upper end of the driving motor 301, the first gear 303 is engaged with the driving gear 302, a cam rod 306 is disposed on the first gear 303, a third gear 308 is rotatably disposed on the base 101, the cam rod 306 is connected with the third gear 308 through a second belt 307, the third gear 308 is coaxially and slidably disposed with a cam rod 305, the cam rod 305 is intermittently engaged with the cam rod 306, one end of the cam rod 305 is provided with a second gear 304, the second gear 304 is intermittently engaged with the first gear 303, the other end of the cam rod 305 is provided with a second bevel gear 309, the second bevel gear 309 is intermittently engaged with the first bevel gear 203, in an initial state, the first gear 305 is engaged with the cam rod 306, the driving gear 302 drives the first gear 303 and the cam rod 306 to rotate, the second gear 307 drives the third gear 308 to rotate, the cam rod 306 moves within the third gear 308, the second cam rod 305 drives the second gear 304 to move with the second gear 309, and the second gear 309 drives the first gear 203 to rotate, and the second bevel gear 309 is engaged with the second bevel gear 203 to rotate, and the first gear 309 is driven to rotate, and the second bevel gear 309 is driven to rotate.

Referring to fig. 1, 5 and 6, the feeding component 4 includes a supporting plate 401 mounted on the base 101, a coating barrel 402 is disposed on the supporting plate 401, a feeding box 403 is disposed at the upper end of the coating barrel 402, one end of the coating barrel 402 coaxially rotates and is provided with a fourth gear 404, a stirring blade 405 and a spiral cone 407 are coaxially disposed on the fourth gear 404, an outlet 408 is disposed at the other end of the coating barrel 402, the fourth gear 404 is meshed with the third gear 308, a second heating wire 406 is disposed inside the coating barrel 402, the lower end of the feeding box 403 is communicated with the stirring blade 405, the fourth gear 404 drives the stirring blade 405 and the spiral cone 407 to synchronously rotate when the fourth gear 404 rotates, the coating is placed in the feeding box 403, the stirring blade 405 rotates to drive the coating to move, the coating is filled in the spiral cone 407, the spiral cone 407 rotates to drive the coating to coat the cable, and simultaneously drive the cable to enter the outlet 408.

Referring to fig. 1, 7 and 8, the cooling assembly 5 includes a wire inlet 506 connected with a wire outlet 408, a cooling barrel 501 is rotatably arranged on the wire inlet 506, a plurality of groups of driven blocks 502 are arranged on the cooling barrel 501, a water tank 504 is arranged on the base 101, the wire inlet 506 is rotatably arranged on the water tank 504, a driving disc 503 is rotatably arranged on the side edge of the water tank 504, a driving column is arranged on the driving disc 503 and is meshed with the driven blocks 502, eight groups of water collecting barrels 505 are fixedly arranged on the cooling barrel 501, an opening is arranged on the water collecting barrels 505, the opening of the water collecting barrels 505 is inclined with the horizontal plane of the base 101, a water leakage port is arranged at one end of the wire inlet 506 close to the base 101, a water inlet is arranged at one end of the heating wire I206 far away from the base 101, two groups of wire pulling wheels II 509 are rotatably arranged on the base 101, rotary teeth are arranged on the two wire pulling wheels II 509 are meshed with each other, a driven plate 508 is coaxially arranged on a second stay wire wheel 509, a second connecting rod 507 is arranged on the driven plate 508, one end of the second connecting rod 507 is connected with the driven plate 508, the other end of the second connecting rod 507 is connected with the rotating plate 204, the middle section of the second connecting rod 507 is connected with the driving plate 503, when the rotating plate 204 rotates, the driving plate 503 and the driven plate 508 are driven by the second connecting rod 507 to rotate simultaneously, the driven plate 508 drives two groups of second stay wire wheels 509 to rotate, the second stay wire wheels 509 drive cables to move, when the driving plate 503 rotates, the cooling barrel 501 drives eight groups of water collecting barrels 505 to rotate, when the water collecting barrels 505 rotate into the water tank 504, water in the water collecting barrels 505 is stored in the water collecting barrels 505, when the cooling barrel 501 drives the water collecting barrels 505 to rotate to the upper side of the first heating wire 206, the water in the water collecting barrels 505 flows into the water inlet 506 through the water inlet 506 to cool the covered cables, meanwhile, water flows out through the water leakage port.

In an embodiment, a method for using an insulating layer coating device for cable production includes the following specific steps:

s1, a cable passes through a groove at the rear end of a first wire pulling wheel 202, and is heated and stretched by a first heating wire 206;

s2, placing the cable stretched in the first wire pulling wheel 202 into the feeding component 4;

s3, placing the coating raw materials into a feeding box 403;

s4, coating the cable through the stirring fan blade 405 and the spiral cone 407;

s5, after the cable coating is completed, the cable enters the wire inlet 506 through the wire outlet 408;

s6, the water in the water tank 504 is continuously poured into the wire inlet 506 through the water collecting barrel 505, and the temperature of the cable coated in the wire inlet 506 is reduced;

s7, winding the coated cable on the winding wheel 103 again.

Working principle: in the initial state, the concave thread rod 305 is meshed with the convex thread rod 306, the driving gear 302 is started, the driving gear 302 drives the first gear 303 and the convex thread rod 306 to rotate, the first gear 303 drives the third gear 308 to rotate through the second belt 307, the convex thread rod 306 drives the concave thread rod 305 to move in the third gear 308, the concave thread rod 305 drives the second gear 304 to move simultaneously with the second bevel gear 309, when the second gear 304 is meshed with the first gear 303, the second bevel gear 309 is meshed with the first bevel gear 203, at the moment, the first gear 303 drives the second gear 304 to rotate, the second gear 304 drives the second bevel gear 305 and the second bevel gear 309 to rotate, the second bevel gear 309 drives the first bevel gear 203 to rotate, when the first bevel gear 203 rotates, the first two groups of wire pulling wheels 202 simultaneously rotate, the driving cables move in the grooves, meanwhile, the first heating wire 206 heats the cable, and the rotating speeds deviate due to the fact that the rotating shafts of the first bevel gear 203 and the first wire pulling wheels 202 are different in size, the cable is stretched, the first bevel gear 203 drives the rotating disc 204 to rotate, the rotating disc 204 drives the driving disc 503 and the driven disc 508 to rotate simultaneously through the second connecting rod 507, the driven disc 508 drives the second stay wire wheels 509 to rotate, the second stay wire wheels 509 drive the cable to move, the driving disc 503 drives the cooling barrel 501 to rotate through the moving block 502, the cooling barrel 501 drives the eight groups of water collecting barrels 505 to rotate, water in the water tank 504 is stored in the water collecting barrel 505 when the water collecting barrel 505 rotates into the water tank 504, when the cooling barrel 501 drives the water collecting barrel 505 to rotate to the upper side of the first heating wire 206, water in the water collecting barrel 505 flows into the water inlet 506 through the water inlet, the coated cable is cooled, meanwhile, the water flows out through the water leakage port, the third gear 308 drives the fourth gear 404 to rotate, the fourth gear 404 drives the stirring fan blades 405 and the spiral cone 407 to synchronously rotate, the coating material is placed in the feeding box 403, falls into the stirring fan blade 405 through the feeding box 403, the stirring is carried out when the stirring fan blade 405 rotates to drive the coating material to move, the coating material is filled into the spiral cone 407, the spiral cone 407 drives the coating material to coat the cable when rotating, meanwhile, the cable is fed into the cable outlet 408, and when the cable is pulled, the cable pulls the release wheel to rotate, and the release wheel drives the take-up wheel to synchronously rotate through the first connecting rod 104.

The present invention is not limited to the above-described embodiments, and various modifications are possible within the scope of the present invention without inventive labor, as those skilled in the art will recognize from the above-described concepts.

Claims (6)

1. Insulating layer cladding equipment for cable production, including rolling subassembly (1), its characterized in that: the winding assembly (1) comprises a base (101), two groups of winding wheels (103) are rotatably arranged at two ends inside the base (101), one group of winding wheels (103) is a winding wheel, the other group of winding wheels (103) is a releasing wheel, one end, close to the releasing wheel, of the base (101) is provided with a mounting plate (201), the mounting plate (201) is rotatably provided with four first stay wire wheels (202), each two stay wire wheels (202) are respectively arranged at two sides of the mounting plate (201), grooves are formed in the first stay wire wheels (202), a first bevel gear wheel (203) is arranged on the first stay wire wheels (202), the first bevel gear wheel (203) is connected with the first bevel gear wheel (202) through a belt (205), the diameter of the shaft of the first bevel gear wheel (203) is smaller than that of the first bevel gear wheel (202) connected with the first bevel gear wheel (205), a motor (204) is coaxially arranged on the first bevel gear wheel (203), a driving motor (206) is coaxially arranged on the first bevel gear wheel (203), a driving assembly (301) is driven by a driving motor (301), the driving assembly (301) is further arranged on the second bevel gear wheel (301), the driving assembly (301) is driven by a motor (308), the novel spiral bevel gear is characterized in that the gear III (308) is rotatably arranged on the base (101), the bevel gear II (309) is meshed with the bevel gear I (203) intermittently, the base (101) is further provided with a feeding component (4), the feeding component (4) comprises a supporting plate (401) arranged on the base (101), a coating barrel (402) is arranged on the supporting plate (401), one end of the coating barrel (402) is provided with a gear IV (404), the other end of the coating barrel (402) is provided with an outlet (408), the gear IV (404) is meshed with the gear III (308), the gear IV (404) is coaxially provided with a stirring fan blade (405) and a spiral cone (407), the base (101) is further provided with a cooling component (5), the cooling component (5) comprises a wire inlet (506) connected with the wire outlet (408), the wire inlet (506) is rotatably provided with a cooling barrel (501), and a plurality of groups of water collecting barrels (505) are arranged on the cooling barrel (506).

The winding assembly (1) further comprises a plurality of groups of rotating rollers (102) rotatably arranged at the bottom of the base (101), the rotating rollers (102) are attached to the winding wheels (103), and the two groups of winding wheels (103) are connected through a first connecting rod (104);

the feeding assembly (4) further comprises a feeding box (403) arranged at the upper end of the coating barrel (402), the feeding box (403) is communicated with the stirring fan blades (405), and a heating wire II (406) is arranged in the gear IV (404).

2. An insulating layer covering apparatus for cable production according to claim 1, wherein: the first wire pulling wheel (202) is provided with teeth, and the two first wire pulling wheels (202) on the same side are meshed through the teeth.

3. An insulating layer covering apparatus for cable production according to claim 1, wherein: the time delay drive assembly (3) further comprises a drive gear (302) arranged on an output shaft of the drive motor (301), a first gear (303) is arranged at the upper end of the drive motor (301), the first gear (303) is meshed with the drive gear (302), a convex pattern rod (306) is arranged on the first gear (303), one end of the first gear (303) is meshed with the drive gear (302), the other end of the first gear (303) is connected with a third gear (308) through a second belt (307), a second gear (304) is coaxially arranged on the third gear (308), the second gear (304) is meshed with the first gear (303) intermittently, a concave pattern rod (305) is arranged on the second gear (304), one end of the concave pattern rod (305) is connected with the second gear (304), the other end of the concave pattern rod (305) is connected with the second bevel gear (309), the concave pattern rod (305) is meshed with the third gear (308) intermittently, and the concave pattern rod (305) is connected with the third gear (308) in a sliding mode.

4. An insulating layer covering apparatus for cable production according to claim 1, wherein: the cooling assembly (5) further comprises a base (101) on be provided with basin (504), inlet (506) rotate and install on basin (504), basin (504) side rotate and be provided with driving disk (503), driving disk (503) on be provided with the actuating post, cooling barrel (501) on be provided with multiunit driven piece (502), actuating post and driven piece (502) meshing, base (101) on rotate and be provided with two and act as go-between and take turns two (509), two and act as go-between and take turns two (509) on be provided with the tooth of rotation, two and act as go-between take turns two (509) intermeshing, one and act as go-between take turns two (509) on coaxial be provided with driven disk (508), driven disk (508) on be provided with connecting rod two (507), connecting rod two (507) one end be connected with driven disk (508), connecting rod two (507) other end be connected with rotating disk (204), connecting rod two (507) and driving disk (503) are connected.

5. The insulating layer covering apparatus for cable production according to claim 4, wherein: the water inlet is arranged at one end of the wire inlet (506) close to the base (101), and a water inlet is arranged at one end of the wire inlet (506) far away from the base (101).

6. A method of using the insulating layer covering apparatus for cable production according to any one of claims 1 to 5, comprising the steps of:

s1, a cable passes through a groove at the rear end of a first stay wire wheel (202), and is heated and stretched by a first heating wire (206);

s2, placing the cable stretched in the first wire pulling wheel (202) into a feeding component (4);

s3, placing the coating raw materials into a feeding box (403);

s4, coating the cable through the stirring fan blade (405) and the spiral cone (407);

s5, after the cable coating is finished, the cable enters a wire inlet (506) through a wire outlet (408);

s6, the water collecting barrel (505) is used for continuously watering the wire inlet (506), and cooling the cable coated in the wire inlet (506);

s7, winding the coated cable on the winding wheel (103) again.